In vitro assessment of the Kirpa Kit™ modified manual single lumen alternating micro-batch (mSLAMB) dialysis device.

BACKGROUND: Access to pediatric dialysis is challenged in low-resource settings due to high costs, scarcity of equipment, and the lack of qualified personnel availability. We demonstrated the manual single lumen alternating micro-batch (mSLAMB) device can remove small solutes in vitro without the need for electricity, batteries, or pumps. We developed a new version (Kirpa Kit™) to address some of the technical limitations of mSLAMB. Here, we compare the in vitro clearance performance and ease of use of the Kirpa Kit™ with that of prior mSLAMB configurations. METHODS: A mixture of expired packed red blood cells, 0.9% NaCl, urea, and heparin was used to test the efficiency of two mSLAMB configurations and the Kirpa Kit™ in removing potassium and urea. Clearance was evaluated by measuring percent reduction after 25-min sessions with each device. A survey was used to evaluate the ease of use of each configuration. RESULTS: The Kirpa Kit™ achieved a median urea reduction of 82.4% and potassium reduction of 82.1%, which were higher than those achieved with the best-performing mSLAMB configuration (urea 71.9%, potassium 75.4%). The Kirpa Kit™ was easier to use with a shorter perceived time of use than the mSLAMB. CONCLUSIONS: The Kirpa Kit™, evolution of mSLAMB, is easy to use and may have improved efficacy, making it an optimal candidate for in vivo testing.

Manual single lumen alternating micro-batch dialysis achieves reliable clearance via diffusion.

BACKGROUND: Acute kidney injury is a cause of preventable deaths in low resource settings due to lack of dialysis access and cost. A manual single lumen alternating micro-batch (mSLAMB) dialysis technique performs kidney replacement therapy using single lumen access, low-cost bags/tubing, intravenous fluids, and a filter without electricity, a battery, or a pump. We propose a protocol whereby mSLAMB can perform diffusive clearance simply and efficiently to bring dialysis to underserved populations. METHODS: Expired packed red blood cells mixed with crystalloid solution were spiked with urea and anticoagulated with heparin. A Static diffusion Technique (with short flushes of fluid before each filter pass) was compared to a Dynamic diffusion Technique (with fluid running through the filter during the forward pass) to assess urea and potassium clearance. Passive ultrafiltration was the difference between the 200 mL batch volume and volume returned to the blood bag per cycle. RESULTS: Five cycles achieved urea reduction ratios (URR) between 17-67% and potassium clearance of 18-60%, with higher percentages achieved from higher proportions of batch volume dialyzed to patient volume. Dynamic Technique increased clearance over the Static Technique. Passive ultrafiltration volumes were 2.5-10% of batch volume. CONCLUSION: mSLAMB dialysis performs diffusive clearance and passive ultrafiltration efficiently, while preserving resources and available manpower. IMPACT: mSLAMB is a dialysis technique that can perform efficient diffusive clearance and passive ultrafiltration without electricity, batteries, or a pump. With basic medical supplies and limited manpower, mSLAMB is a cost-effective means of providing emergency dialysis in low resource areas. We propose a basic algorithm for safe and cost-effective dialysis for people of different ages and sizes.

Manual Single-Lumen Alternating Micro-Batch Device as Renal Replacement Therapy in Austere Environments.

INTRODUCTION: Electrolyte derangements, acidosis, and volume overload remain life-threatening emergencies in people with acute kidney injury in austere environments. A single-lumen alternating micro-batch (SLAMB) dialysis technique was designed to perform renal replacement therapy using a single-lumen access, low-cost disposable bags and tubing, widely available premade fluids, and a dialysis filter. A manual variation (mSLAMB) works without electricity, battery, or a pump. We modeled mSLAMB dialysis and predicted it could achieve adequate small solute clearance, blood flow rates, and ultrafiltration accuracy. METHODS: A 25- to 30-kg pediatric patient's blood volume was simulated by a 2-L bag of expired blood and spiked with 5 g of urea initially, then with 1-2 g between experiments. Experiments had 8 cycles totaling prescription volumes of 800-2,400 mL and were conducted with different ratios of hemofiltration fluid to blood volume. Concentrations of urea and potassium, final effluent volumes, and cycle duration were measured at the end of each cycle to determine clearance, ultrafiltration accuracy, and blood flow rates. RESULTS: Each cycle lasted 70-145 s. Experiments achieved a mean urea reduction ratio of 27.4 ± 7.1% and a mean potassium reduction of 23.4 ± 9.3%. The largest urea and potassium reduction percentage occurred with the first cycle. Increased hemofiltration fluid to blood volume ratio did not increase clearance. Mean (+/- standard deviation) blood flow ranged from 79.7 +/- 4.4 mL/min to 90.8 +/- 6.5 mL/min and increased with larger batch volume and height difference between reservoirs. Ultrafiltration accuracy ranged from 0 to 2.4% per cycle. DISCUSSION: mSLAMB dialysis is a simple, manual, cost-effective mode of dialysis capable of providing clearance and accurate ultrafiltration. With further refinement of technique, we believe this can be a potentially lifesaving treatment in austere conditions and low-resource settings.